Dense functional and molecular readout of a circuit hub in sensory cortex

Although single-cell transcriptomics of the neocortex has uncovered more than 300 putative cell types, whether this molecular classification predicts distinct functional roles is unclear. We combined two-photon calcium imaging with spatial transcriptomics to functionally and molecularly investigate cortical circuits. We characterized behavior-related responses across major neuronal subclasses in layers 2 or 3 of the primary somatosensory cortex as mice performed a tactile working memory task. We identified an excitatory intratelencephalic cell type, Baz1a, that exhibits high tactile feature selectivity. Baz1a neurons homeostatically maintain stimulus responsiveness during altered experience and show persistent enrichment of subsets of immediately early genes. Functional and anatomical connectivity reveals that Baz1a neurons residing in upper portions of layers 2 or 3 preferentially innervate somatostatin-expressing inhibitory neurons. This motif defines a circuit hub that orchestrates local sensory processing in superficial layers of the neocortex.

Automated summary

Functional and molecular investigation of cortical circuits using two-photon calcium imaging combined with spatial transcriptomics. Identification of an excitatory cell type with high tactile feature selectivity that maintains stimulus responsiveness during altered experience. The cell type preferentially interacts with inhibitory neurons, defining a circuit hub for local sensory processing in superficial layers of the neocortex.